Optimization of the Imaged cIEF Method for Monitoring the Charge Heterogeneity of Antibody-Maytansine Conjugate.

The aim of this study was to develop a whole-column imaging-detection capillary isoelectric focusing (icIEF) method for the analytical characterization of charge heterogeneity of a novel humanized anti-EphA2 antibody conjugated to a maytansine derivative. In addition to focusing time, sample composition was optimized: pH range, percent of carrier ampholytes, conjugated antibody concentration, and urea concentration. A good separation of charge isoforms was obtained with 4% carrier ampholytes of a large (3-10) and narrow pH range (8-10.5) (1 : 1 ratio), conjugated antibody concentration (0.3-1 mg/ml) with a good linearity (R2: 0.9905), 2 M of urea concentration, and 12 minute for focusing. The optimized icIEF method demonstrated a good interday repeatability with RSD values: <1% (pI), <8% (% peak area), and 7% (total peak areas). The optimized icIEF was useful as an analytical characterization tool to assess the charged isoform profile of a discovery batch of the studied maytansinoid-antibody conjugate in comparison to its naked antibody. It exhibited a large pI range (7.5-9.0), while its naked antibody showed a narrow pI range (8.9-9.0). In the discovery batch of maytansinoid-antibody conjugate, 2% of charge isoforms had the same pI as the pI of naked antibody isoforms.

Hydrophilic interaction liquid chromatography for dalargin separation from its structural analogues and side products.

Retention behaviour of Dalargin and five peptide analogues of Leu-enkephalin, has been extensively studied by hydrophilic interaction liquid chromatography (HILIC) on a bare silica stationary phase (Atlantis® HILIC silica). The influence of buffer pH, ionic strength, and organic modifier content on peptide retentions was examined. Variation of organic modifier content (70-90% ACN) shows that, as expected, the most polar peptide, Dalargin, is the most retained. Moreover, at acidic pH, the retention mechanism for all the peptides studied seems to rely, mainly, on adsorption phenomenon. By varying the pswH buffer (between 4.4-7.5), we observed that the retention of all the peptides was mainly governed by their total number of charges, whatever the variation (increase or decrease) of their retention factor. At pswH 7.5, an increase of the cationic counter-ion concentration (NH4+) lead to a decrease of the retention factor of Dalargin, suggesting a weak cation exchange for this peptide. For the other peptides, the variation of the retention factors was negligible between 5-15mM. Above 15mM, the retention factors of all the peptides increased, probably due to an increase of the water layer thickness at the surface of the stationary phase. In the second part of the study, qualitative analysis of non-purified dalargin, resulting from solid-phase synthesis, was realized. Optimisation of the separation of the target peptide from its side products has been first performed with UV detection. Then, by coupling the HILIC column with ESI-MS, using the optimal separation conditions, it was possible to identify Dalargin and to propose the amino-acids sequence of its side-products.

Hexylacrylate-based mixed-mode monolith, a stationary phase for the nano-HPLC separation of structurally related enkephalins.

The potential of an in situ photopolymerized hexylacrylate-based monolithic stationary phase-bearing sulfonic acid groups was investigated by studying the chromatographic retention of small structurally related peptides (enkephalins) by nano-LC. Several retention mechanisms were highlighted. First, a reverse-phase chromatographic behavior toward neutral solutes due to hexylacrylate-moieties was demonstrated. Second, an evaluation of the influences of buffer pH suggested the involvement of a cation-exchange mechanism due to the presence of 2-acrylamido-2-methyl-1-propanesulfonic acid. This cation-exchange phenomenon was confirmed by the clear influence of Na(+) concentration in the mobile phase on peptide retention.

High performance liquid chromatography separation of structurally related enkephalins on quaternary ammonium-embedded stationary phase in isocratic mode.

Separation of twelve enkephalins was investigated on a quaternary ammonium-embedded stationary phase (Stability BS-C23). Variation of buffer pH of the mobile phase highlighted the complex relationship between repulsive/attractive electrostatic interactions and the reversed-phase partitioning mechanism. The effect of three different anions employed as additives (phosphate, chloride and perchlorate) was examined at various concentrations and two pH values (acidic and neutral). At pH 2.5, an increase in the anion eluent concentration resulted in a higher retention factors of positively charged enkephalins. This effect was more pronounced when perchlorate ions were added to the mobile phase rather than phosphate and chloride ions, due to chaotropic and ion-pairing effects. In contrast, at pH 7.5, retention factors of negatively charged enkephalins decreased when these salts were added, due to an anion-exchange mechanism. Perchlorate caused a sharper decrease than chloride and phosphate anions did. The results presented here provide insight into the possible adjustment of retention and separation of peptides on a mixed-mode stationary phase (BS-C23) by a careful control of the buffer pH, the nature and concentration of anions, added to the buffer, and organic modifier content.